CN114858812B - Detection system for non-woven fabric production - Google Patents

Abstract

The invention discloses a detection system for non-woven fabric production, which belongs to the technical field of non-woven fabric detection and comprises a feeding device, a detection device and a winding device; detection device is including detecting the frame, detect motion and detect the head, it includes x axle motion subassembly to detect motion, the sliding seat, y axle motion subassembly and installed part, x axle motion subassembly includes two worms, the worm wheel, x axle guide bar, two worm parallel arrangement and all rotate and install in detecting the frame, the worm wheel is located between two worms and meshes with two worms respectively, it is provided with two worm pivoted driving pieces of drive to detect the frame, x axle guide bar fixed mounting is in detecting the frame, x axle guide bar wears to locate the sliding seat and slides the cooperation with the sliding seat, worm wheel and sliding seat normal running fit, y axle motion subassembly sets up in the sliding seat and is used for driving the installed part and moves along y axle direction, it installs in the installed part to detect the head. This application has the effect of being convenient for realize the reinspection processing to the non-woven fabrics.

Description

Detection system for non-woven fabric production

Technical Field

The invention relates to the field of non-woven fabric detection, in particular to a detection system for non-woven fabric production.

Background

The non-woven fabric is a fabric formed without spinning and weaving, is usually produced by adopting polyester fiber and polyester fiber materials and is manufactured by a needling process, and can be made into fabrics with different thicknesses, handfeel, hardness and the like. The non-woven fabric has the characteristics of moisture resistance, air permeability, flexibility, lightness, thinness, flame retardance, no toxicity, no odor, low price, recycling and the like, and can be widely applied to different industries.

The nonwoven fabric is usually subjected to a detection process after the production is completed to detect whether the nonwoven fabric meets the end use requirements. In the related art, a detection head reciprocating in a horizontal direction is used for detecting the surface of the non-woven fabric during conveying, infrared ray or camera shooting is performed on the surface of the non-woven fabric, the conveying of the non-woven fabric is suspended after a defect is found in the detection process, and a worker marks the defect.

In view of the above-mentioned related art, the inventor believes that the position of the nonwoven fabric after the conveyance is stopped usually deviates from the original detection position to some extent, and the detection head reciprocating in the horizontal direction does not facilitate the re-inspection of the nonwoven fabric.

Disclosure of Invention

In order to facilitate the realization to the reinspection processing of non-woven fabrics, this application provides a detecting system for non-woven fabrics production.

The application provides a detecting system for non-woven fabrics production adopts following technical scheme:

a detection system for non-woven fabric production comprises a feeding device, a detection device and a winding device, wherein the feeding device is used for feeding non-woven fabrics;

the detection device comprises a detection frame, a detection movement mechanism and a detection head, wherein the detection movement mechanism comprises an x-axis movement assembly, a sliding seat, a y-axis movement assembly and an installation piece, the x-axis movement assembly comprises two worms, a worm wheel and an x-axis guide rod, the two worms are arranged in parallel and are both rotatably installed on the detection frame, the worm wheel is positioned between the two worms and is respectively meshed with the two worms, the detection frame is provided with a driving piece for driving the two worms to rotate, the x-axis guide rod is fixedly installed on the detection frame, the x-axis guide rod penetrates through the sliding seat and is in sliding fit with the sliding seat, the worm wheel is in rotating fit with the sliding seat, the y-axis movement assembly is arranged on the sliding seat and is used for driving the installation piece to move along the y-axis direction, and the detection head is installed on the installation piece; the winding device is used for winding the detected non-woven fabric.

Through adopting above-mentioned technical scheme, the non-woven fabrics carries out the material loading via loading attachment and carries to the test rack after, when driving piece drive two worms carried out the syntropy and rotates, the worm wheel makes the sliding seat drive the installed part and detect the first motion that together carries out the horizontal direction under the limiting displacement of x axle guide bar because of the meshing with the worm, thereby realize the surface detection when carrying the non-woven fabrics, discover flaw point in the testing process, when stopping to carry the non-woven fabrics, carry out the horizontal motion of y axle direction through y axle motion subassembly drive installed part and can realize the reinspection processing to the non-woven fabrics horizontal direction different position, thereby be convenient for reduce the error that appears in the non-woven fabrics testing process, and also be convenient for the staff after the reinspection of non-woven fabrics realizes the more accurate mark processing to non-woven fabrics flaw department, the self-locking effect between two worms and the worm wheel is favorable to fully guaranteeing the stability of position behind the sliding seat horizontal motion.

Optionally, the y-axis motion assembly comprises a driven gear and a y-axis guide rod, the driven gear is coaxially and fixedly connected to the worm wheel, the mounting part is provided with teeth which are distributed along the y-axis direction and meshed with the driven gear, the y-axis guide rod is fixedly installed on the mounting part, and the y-axis guide rod penetrates through the sliding seat and is matched with the sliding seat in a sliding manner.

Through adopting above-mentioned technical scheme, when two worms rotated around self axis when opposite direction, the worm wheel drove driven gear and together rotated around self axis, the installed part drives the motion that detects the head and together carry out y axle direction because of tooth and driven gear's meshing, thereby be convenient for detect the head and carry out reinspection to the non-woven fabrics of y axle direction different positions, two worms can realize the motion of worm wheel x axle direction or around the rotation of self axis direction through syntropy or not equidirectional rotation, need not extra driving source, and easy and simple to handle, and when self-locking effect between worm wheel and worm guaranteed worm wheel rotation back place stability, still be favorable to guaranteeing the stability of installed part removal back place.

Optionally, the y-axis guide rod is in sliding fit with two limiting rings, and the limiting rings are tightly abutted by bolts and fixed with the y-axis guide rod.

Through adopting above-mentioned technical scheme, the setting of spacing ring can carry on spacingly to the motion of installed part along y axle horizontal direction for the installed part is difficult for breaking away from the sliding seat, and simultaneously, supports tight setting through the bolt and makes the position of spacing ring adjust, is convenient for adjust the slip stroke of installed part.

Optionally, the top of worm wheel rotates and is connected with the sliding block, the sliding tray along the horizontal extension of x axle direction is seted up to the test rack, the sliding block be located the sliding tray and with sliding tray sliding fit.

Through adopting above-mentioned technical scheme, the horizontal limiting displacement when the sliding block moves along the x axle direction to the worm wheel is played in the cooperation of sliding tray, makes the displacement of vertical direction difficult to appear when the worm wheel moves along the x axle direction simultaneously, is favorable to further guaranteeing the stability when two worms drive the worm wheel and remove.

Optionally, the detection frame is provided with a nip roll and a nip lifting assembly, the nip roll is rotatably mounted on the detection frame, and the nip lifting assembly is used for driving the nip roll to move along the vertical direction.

Through adopting above-mentioned technical scheme, when the pressure roll moves the non-woven fabrics of carrying along vertical direction and supports the pressure, be favorable to guaranteeing the stability when non-woven fabrics is carried, and then be favorable to guaranteeing that the detection head detects the detection effect when the non-woven fabrics of carrying.

Optionally, press material lifting unit to include and press material seat, installation piece, press material motor, press the material lead screw and press the material guide bar, it is all just to being provided with two to press material seat and installation piece, press the material lead screw to rotate and install in one of them pressure material seat, press the material lead screw to wear to locate one of them installation piece and with installation piece screw-thread fit along vertical direction, press the material motor to be used for the drive to press the material lead screw to rotate, guide bar fixed mounting is in another installation piece, the guide bar is worn to locate another installation piece and with installation piece sliding fit along vertical direction, press the both ends of material roller length direction to rotate respectively and install in two installation pieces.

Through adopting above-mentioned technical scheme, when pressing material motor drive material lead screw and rotating, two installation pieces drive the nip rolls and move along vertical direction under the limiting displacement who presses the material guide bar, the setting up of pressing the material motor makes staff's drive nip rolls along the convenient quick of motion of vertical direction, and simultaneously, when the non-woven fabrics of carrying stops carrying, can further carry on spacingly to the non-woven fabrics of carrying through the motion of nip rolls along vertical direction, make the non-woven fabrics have less displacement deviation after stopping carrying, be convenient for realize stopping the reinspection after carrying the non-woven fabrics.

Optionally, detection device still includes observation frame and observation board, observation board top-down slope sets up and fixed mounting in observation frame, observation frame rotates and installs a plurality of detection guide rolls that are used for leading to carrying the non-woven fabrics, the observation board is installed and is supported the pressure subassembly, support the pressure subassembly including being used for supporting the pinch roller that presses to the non-woven fabrics of carrying.

Through adopting above-mentioned technical scheme, the setting of observation frame and observation board is convenient for the audio-visual non-woven fabrics to carrying of staff and is observed, is favorable to further guaranteeing the detection quality to the non-woven fabrics, and simultaneously, the support of support pinch roller pair non-woven fabrics is favorable to guaranteeing the stability of non-woven fabrics when the observation board conveys.

Optionally, the observation frame is provided with a light barrier, the light barrier is provided with a plurality of light guide cylinders obliquely facing the observation panel, the axis of each light guide cylinder is perpendicular to the surface of the observation panel, and each light guide cylinder is internally provided with an observation lamp.

Through adopting above-mentioned technical scheme, the setting of barn door and leaded light section of thick bamboo plays the gathering effect to light, is favorable to the audio-visual non-woven fabrics of being located the observation board and carrying of staff to observe to be favorable to further guaranteeing the detection effect of non-woven fabrics.

Optionally, the abutting assembly further comprises an adjusting roller and an abutting seat, the adjusting roller is horizontally arranged on the observation frame, the adjusting roller is horizontally arranged on the observation plate, the adjusting roller penetrates through the abutting seat along the x-axis direction and is matched with the abutting seat in a sliding manner, the abutting seat is tightly fixed on the adjusting roller through a bolt, and the abutting wheel is rotatably arranged on the abutting seat.

Through adopting above-mentioned technical scheme, support and press the seat to adjust through the length direction that the adjusting roller can be followed to the bolt of unscrewing or screwing up to non-woven fabrics when being convenient for support and press the transport of wheel pair equidirectional not carries on spacingly, and the suitability is strong.

It is optional, the coiling mechanism includes rolling frame, two rolling live rollers, wind-up roll and two screens pieces, two the rolling live roller rotates to be installed in the rolling frame and distributes along the x axle direction, the wind-up roll is located between two rolling live rollers, two the screens piece all has the rolling regulation pole that a level set up, the rolling regulation pole is worn to locate the rolling frame and is slided the cooperation with the rolling frame along the x axle direction, the rolling regulation pole supports tightly through the bolt and fixes with the rolling frame.

Through adopting above-mentioned technical scheme, the wind-up roll is finally around locating after the non-woven fabrics detects the completion, and when two rolling live rollers rotated, the wind-up roll realized the rolling to the non-woven fabrics, and two rolling regulation poles can carry out the regulation of x axle direction to the take-up roll of being convenient for get put and can carry on spacingly to the position of wind-up roll, the stability of position when being favorable to guaranteeing the wind-up roll to the non-woven fabrics rolling.

In summary, the present application includes at least one of the following beneficial technical effects:

1. when discovering the flaw point in the testing process, when stopping carrying the non-woven fabrics, carry out the horizontal motion of y axle direction through y axle motion subassembly drive installed part and can realize the reinspection processing to the non-woven fabrics different position of horizontal direction to be convenient for reduce the error that appears in the non-woven fabrics testing process, and also be convenient for the staff after the reinspection of non-woven fabrics and realize handling the more accurate mark of non-woven fabrics flaw department.

2. The two worms can realize the movement of the x-axis direction of the worm wheel or the rotation around the axis direction of the worm wheel through the rotation in the same direction or different directions, an additional driving source is not needed, the operation is simple and convenient, and the self-locking effect between the worm wheel and the worm is favorable for ensuring the stability of the position of the mounting part after the movement when the position stability of the worm wheel is ensured.

3. The horizontal limiting effect when the sliding block and the cooperation of sliding tray play and remove the worm wheel along the x axle direction makes the displacement of vertical direction difficult to appear when the worm wheel removes along the x axle direction simultaneously, is favorable to further guaranteeing the stability when two worms drive the worm wheel and remove.

Drawings

Fig. 1 is a schematic overall structure diagram of an embodiment of the present application.

Fig. 2 is a schematic partial cross-sectional view of a detection frame in an embodiment of the present application.

Fig. 3 is a partially enlarged schematic view of a portion a in fig. 2.

Fig. 4 is a partially cross-sectional schematic view of the light barrier in the embodiment of the present application.

Description of reference numerals:

1. a feeding frame; 2. a feeding roller; 3. a feeding guide roller; 4. a detection frame; 401. a detection table; 402. detecting a frame; 5. a detection head; 6. detecting a conveying roller; 7. a material pressing seat; 8. mounting a block; 9. a material pressing motor; 10. pressing screw rods; 11. a material pressing guide rod; 12. a movable groove; 13. a sliding seat; 14. a mounting member; 15. a worm; 16. a worm gear; 17. an x-axis guide bar; 18. detecting a motor; 19. a connecting shaft; 20. a slider; 21. a sliding groove; 22. a driven gear; 23. a y-axis guide bar; 24. a limiting ring; 25. an observation frame; 26. an observation plate; 27. detecting a guide roller; 28. a regulating roller; 29. a pressing seat; 30. pressing the wheel; 31. a light barrier; 32. a light guide tube; 33. an observation lamp; 34. a winding frame; 35. rolling a rotating roller; 36. a wind-up roll; 37. a clamping piece; 38. a winding guide roller; 39. observing the guide roller; 40. a material receiving guide roller; 41. a winding motor; 42. a winding adjusting rod; 43. a limiting cylinder; 44. an observation seat; 45. a nip roll.

Detailed Description

The present application is described in further detail below with reference to figures 1-4.

The embodiment of the application discloses a detecting system for non-woven fabric production. Referring to fig. 1, a detecting system for non-woven fabric production includes loading attachment, detection device and coiling mechanism, and wherein, loading attachment includes material loading frame 1, material loading roller 2 and two material loading guide rolls 3, and material loading roller 2 and two material loading guide rolls 3 all rotate horizontally and install in material loading frame 1, and material loading roller 2 is higher than two material loading guide rolls 3 and is located the height.

Referring to fig. 1 and 2, in the present embodiment, the direction of conveyance of the nonwoven fabric is defined as the y-axis direction, and the width direction of the nonwoven fabric, i.e., the longitudinal direction of the feed roller 2 is defined as the x-axis direction. Two material loading guide rolls 3 distribute along the y axle direction, and around the non-woven fabrics of rolling up in material loading roller 2 enter into to detection device in proper order around locating behind two material loading guide rolls 3 and carry, stability when two material loading guide rolls 3 set up and be favorable to guaranteeing the non-woven fabrics and carry to detection device.

With continued reference to fig. 1 and 2, the detection device comprises a detection frame 4, a detection movement mechanism and a detection head 5, wherein the detection frame 4 comprises a detection table 401 and a detection frame 402 fixedly installed at the top of the detection table 401, detection conveying rollers 6 horizontally arranged are rotatably installed on two sides of the detection table 401 in the y-axis direction, and non-woven fabrics are conveyed from the tops of the two detection conveying rollers 6 so as to ensure the stability of the non-woven fabrics during conveying.

Referring to fig. 2, it is provided with nip rolls 45 and presses material conveyor components to examine test table 401 top, press the material subassembly to include and press material seat 7, installation piece 8, press material motor 9, press material lead screw 10 and press material guide bar 11, press material seat 7 and installation piece 8 just to being provided with two and all being located the one side that detects frame 402 towards feed roll 2, press material seat 7 all to set up along x axle direction and run through the movable groove 12 that presses material seat 7, two installation pieces 8 are located two movable grooves 12 respectively and follow vertical direction and press material seat 7 sliding fit.

With reference to fig. 2, the pressing screw rod 10 is vertically and rotatably mounted on one of the pressing seats 7, and the pressing screw rod 10 penetrates through one of the mounting blocks 8 along the length direction thereof and is in threaded fit with the mounting block 8. The pressing motor 9 is installed at the top of one of the pressing seats 7, and the pressing screw rod 10 is fixedly installed at the output end of the pressing motor 9, so that the pressing motor 9 drives the pressing screw rod 10 to rotate. Press the vertical fixed mounting of material guide bar 11 in another pressure material seat 7, press material guide bar 11 to wear to locate another installation piece 8 along self length direction and slide the cooperation, press material roller 45 length direction's both ends to rotate respectively and install in two installation pieces 8, so that press material motor 9 drive to press material lead screw 10 when rotating, two installation pieces 8 drive press material roller 45 and move along vertical direction under the limiting displacement who presses material guide bar 11, when press material roller 45 supports when pressing the non-woven fabrics of carrying, be favorable to guaranteeing the stability when the non-woven fabrics is carried, and then be favorable to guaranteeing to detect head 5 and detect the detection effect of time measuring to the non-woven fabrics of carrying.

Referring to fig. 2 and 3, the detection movement mechanism includes an x-axis movement assembly, a sliding seat 13, a y-axis movement assembly, and a mounting member 14, wherein the x-axis movement assembly includes two worms 15, a worm wheel 16, and an x-axis guide rod 17, the two worms 15 are arranged in parallel and extend along the x-axis direction, both the worms 15 are horizontally and rotatably mounted on a detection frame 402, the worm wheel 16 is located between the two worms 15 and respectively engaged with the two worms 15, the detection frame 402 is provided with two driving members, in this embodiment, the driving members are selected as two detection motors 18 mounted on one side of the detection frame 402 in the x-axis direction, and the two detection motors 18 are respectively used for driving the two worms 15 to rotate. When the two detection motors 18 drive the two worms 15 to rotate in the same direction, the worm wheel 16 moves horizontally along the x-axis direction.

Referring to fig. 3, in order to ensure the stability of the worm wheel 16 when moving along the x-axis direction, the worm wheel 16 is coaxially and fixedly connected with a connecting shaft 19, the top of the connecting shaft 19, namely, one end of the connecting shaft 19, far away from the detection table 401, is rotatably connected with a sliding block 20, the detection frame 402 is provided with a sliding groove 21 horizontally extending along the x-axis direction, and the sliding block 20 is located in the sliding groove 21 and is in sliding fit with the sliding groove 21 so as to play a role in limiting the movement of the worm wheel 16. The connecting shaft 19 penetrates through the sliding seat 13 and is in running fit with the sliding seat 13, two x-axis guide rods 17 and the worm 15 are arranged in parallel and are both fixedly installed on the detection frame 4, and the two x-axis guide rods 17 penetrate through the sliding seat 13 and are in sliding fit with the sliding seat, so that when the worm wheel 16 moves along the x-axis direction, the sliding seat 13 moves along with the worm wheel 16.

Referring to fig. 2 and 3, the y-axis movement assembly comprises a driven gear 22 and a y-axis guide rod 23, the driven gear 22 is coaxially and fixedly connected to the bottom of the connecting shaft 19, the mounting part 14 is provided with teeth distributed along the y-axis direction and meshed with the driven gear 22, the y-axis guide rod 23 is fixedly connected to the mounting part 14, the y-axis guide rod 23 horizontally penetrates through the sliding seat 13 along the y-axis direction and is in sliding fit with the sliding seat 13, and the detection head 5 is fixedly mounted on the mounting part 14. When two pairs of worms 15 rotate around the axis of the worm in the opposite direction, the worm wheel 16 drives the driven gear 22 to rotate around the axis of the worm, and the mounting part 14 drives the detection head 5 to move in the y-axis direction together due to the meshing of the teeth and the driven gear 22, so that the detection head 5 can perform rechecking on non-woven fabrics at different positions in the y-axis direction conveniently.

With continued reference to fig. 2 and 3, in order to limit the movement of the mounting member 14 driving the detection head 5 along the y-axis horizontal direction, the outer peripheral surface of the y-axis guide rod 23 is slidably fitted with two limit rings 24, and the material of the limit rings 24 is selected from rubber, so that the sliding seat 13 is not easily damaged due to collision when abutting against the limit rings 24. The spacing ring 24 all supports tightly through the bolt and fixes with y axle guide bar 23 to make the spacing ring 24 can fix at the different length direction of y axle guide bar 23, thereby be convenient for adjust the stroke of installed part 14 and detection head 5, the suitability is strong.

Referring to fig. 4, the detection device further includes an observation frame 25 and an observation plate 26, the observation frame 25 is located on one side of the detection frame 4 far away from the feeding frame 1, the observation plate 26 is obliquely arranged from top to bottom and is fixedly mounted on the observation frame 25, and one end of the observation plate 26 facing the detection frame 4 is a higher end. The observation frame 25 is provided with a plurality of detection guide rollers 27 distributed along the vertical direction in a rotating manner towards one side of the detection frame 4, and the non-woven fabric is sequentially wound on the detection guide rollers 27 during conveying so as to preliminarily ensure the stability of the non-woven fabric during conveying through the observation plate 26.

Referring to fig. 1 and 4, for further guarantee the stability of non-woven fabrics when observing board 26 and carrying, it supports the subassembly to observe board 26 and be provided with, support and press the subassembly to include adjusting roller 28, support and press seat 29 and support pinch roller 30, adjusting roller 28 horizontal rotation is installed in observation frame 25, adjusting roller 28 is worn to locate along the x axle direction and is supported and press seat 29 and with support and press the cooperation that slides of seat 29, support and press seat 29 to support tightly to be fixed in adjusting roller 28 through the bolt, support and press wheel 30 to rotate and install in supporting and press seat 29, so that support pinch roller 30 and can carry on spacingly to the non-woven fabrics when the not equidirectional transport, the suitability is strong and be favorable to further guaranteeing the stability of non-woven fabrics when observing board 26 and carrying.

With reference to fig. 1 and 4, a horizontally disposed light barrier 31 is installed at the top of the observation frame 25, a plurality of light guide cylinders 32 which are distributed along the x-axis direction and obliquely face the observation plate 26 are installed on the light barrier 31, the axis of each light guide cylinder 32 is perpendicular to the surface of the observation plate 26, and an observation lamp 33 is installed in each light guide cylinder 32, so as to perform light condensing and irradiation on the non-woven fabric when the non-woven fabric is conveyed by the observation plate 26, thereby being more beneficial to the staff to visually observe the non-woven fabric conveyed by the observation plate 26.

Referring to fig. 4, the winding device includes a winding frame 34, two winding rotating rollers 35, a winding roller 36 and two blocking members 37, the winding frame 34 is located on one side of the observation frame 25 away from the detection frame 4, and an observation seat 44 is arranged between the winding frame 34 and the observation frame 25, so that a worker can stand on the observation seat 44 to visually observe the non-woven fabric of the observation plate 26. Two horizontal winding guide rollers 38 are rotatably mounted on two sides of the y-axis direction of the observation seat 44, a horizontal observation guide roller 39 is rotatably mounted on one side of the observation frame 25 facing the observation seat 44, the observation guide roller 39 is positioned at the bottom of the observation plate 26, and the non-woven fabric is conveyed to sequentially bypass the outer peripheral surfaces of the observation guide roller 39 and the two winding guide rollers 38 so as to ensure the stability of the non-woven fabric during winding.

Referring to fig. 1 and 4, the winding frame 34 is rotatably provided with a plurality of material receiving guide rollers 40 distributed along the vertical direction, and the non-woven fabric can be wound around the material receiving guide rollers 40 arranged at different positions and then around the winding roller 36 according to actual needs during conveying, so that the stability of the non-woven fabric during winding is further ensured. The two winding rotating rollers 35 extend along the x-axis direction and are rotatably mounted on the winding frame 34, the winding frame 34 is provided with two winding motors 41, and the two winding motors 41 are respectively used for driving the two winding rotating rollers 35 to rotate. The winding roller 36 is located in a gap between the two winding rotating rollers 35, one side of each clamping piece 37 away from each other is provided with a winding adjusting rod 42 which is horizontally arranged, and the cross section of each winding adjusting rod 42 is square.

Referring to fig. 4, the winding frame 34 has two limiting cylinders 43 facing each other and extending along the x-axis direction, two winding adjusting rods 42 respectively penetrate through the two limiting cylinders 43 and are in sliding fit with the limiting cylinders 43, and the two winding adjusting rods 42 are respectively fixed to the two limiting cylinders 43 through bolts. When two rolling motor 41 drive two rolling live rollers 35 and rotate around the same direction, wind-up roll 36 can realize the rolling to the non-woven fabrics, and two rolling regulation poles 42 can carry out the regulation of x axle direction to be convenient for getting of wind-up roll 36 and can spacing to wind-up roll 36's position, the stability of position when being favorable to guaranteeing wind-up roll 36 to the non-woven fabrics rolling.

The implementation principle of the detection system for non-woven fabric production in the embodiment of the application is as follows: after the non-woven fabrics are fed and conveyed to the detection frame 4 through the feeding roller 2, the two detection motors 18 drive the two worms 15 to rotate in the same direction, and the worm wheel 16 is meshed with the worm 15, so that the sliding seat 13 drives the mounting part 14 and the detection head 5 to move in the horizontal direction together under the limiting effect of the x-axis guide rod 17, and surface detection during conveying of the non-woven fabrics is achieved.

Found the flaw point in the testing process, to the non-woven fabrics stop to carry and when the non-woven fabrics of carrying is stabilized spacing through the motion of the vertical direction of nip rolls 45, rotate towards opposite direction through two motor 18 drives that detect, worm wheel 16 drives driven gear 22 and together rotates around self axis this moment, installed part 14 drives the motion that detects head 5 and together carry out the y axle direction because of tooth and driven gear 22's meshing, thereby be convenient for detect head 5 and carry out recheck to the non-woven fabrics of the different positions of y axle direction, and then be convenient for reduce the error that appears in the non-woven fabrics testing process, and also be convenient for the staff after the recheck realize handling the more accurate mark of non-woven fabrics flaw department, the self-locking effect between two worms 15 and worm wheel 16 is favorable to fully guaranteeing the stability of position behind the sliding seat 13 horizontal motion.

The above are preferred embodiments of the present application, and the scope of protection of the present application is not limited thereto, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (9)

1. A detecting system for non-woven fabric production, which characterized in that: the non-woven fabric winding device comprises a feeding device, a detection device and a winding device, wherein the feeding device is used for feeding non-woven fabrics;

the detection device comprises a detection frame (4), a detection movement mechanism and a detection head (5), wherein the detection movement mechanism comprises an x-axis movement assembly, a sliding seat (13), a y-axis movement assembly and an installation piece (14), the x-axis movement assembly comprises two worms (15), a worm wheel (16) and an x-axis guide rod (17), the two worms (15) are arranged in parallel and are rotatably installed on the detection frame (4), the worm wheel (16) is positioned between the two worms (15) and is respectively meshed with the two worms (15), the detection frame (4) is provided with a driving piece for driving the two worms (15) to rotate, the x-axis guide rod (17) is fixedly installed on the detection frame (4), the x-axis guide rod (17) penetrates through the sliding seat (13) and is in sliding fit with the sliding seat (13), the worm wheel (16) is in rotating fit with the sliding seat (13), the y-axis movement assembly is arranged on the sliding seat (13) and is used for driving the installation piece (14) to move along the y-axis direction, and the detection head (5) is installed on the installation piece (14);

the winding device is used for winding the detected non-woven fabric;

y axle motion subassembly includes driven gear (22) and y axle guide bar (23), driven gear (22) coaxial fixed connection is in worm wheel (16), installed part (14) are provided with along y axle direction distribution and with driven gear (22) engaged with tooth, y axle guide bar (23) fixed mounting is in installed part (14), y axle guide bar (23) wear to locate sliding seat (13) and with sliding seat (13) sliding fit.

2. A detection system for the production of non-woven fabric according to claim 1, characterized in that: the y-axis guide rod (23) is in sliding fit with two limiting rings (24), and the limiting rings (24) are tightly abutted and fixed with the y-axis guide rod (23) through bolts.

3. A detection system for the production of non-woven fabric according to claim 1, characterized in that: the top of worm wheel (16) rotates and is connected with sliding block (20), sliding tray (21) along the horizontal extension of x axle direction are seted up in testing frame (4), sliding block (20) are located sliding tray (21) and with sliding tray (21) sliding fit.

4. A detection system for the production of non-woven fabric according to claim 1, characterized in that: the detection frame (4) is provided with a nip roll (45) and a nip lifting assembly, the nip roll (45) is rotatably installed on the detection frame (4), and the nip lifting assembly is used for driving the nip roll (45) to move along the vertical direction.

5. A detection system for the production of non-woven fabric according to claim 4, characterized in that: press material lifting unit to include and press material seat (7), installation piece (8), press material motor (9), press material lead screw (10) and press material guide bar (11), press material seat (7) and installation piece (8) all just to being provided with two, press material lead screw (10) to rotate to install in one of them pressure material seat (7), press material lead screw (10) to wear to locate one of them installation piece (8) and with installation piece (8) screw-thread fit along vertical direction, press material motor (9) to be used for driving to press material lead screw (10) to rotate, press material guide bar (11) fixed mounting in another installation piece (8), press material guide bar (11) to wear to locate another installation piece (8) and with installation piece (8) sliding fit along vertical direction, press material roller (45) length direction's both ends to rotate respectively and install in two installation pieces (8).

6. A detection system for the production of non-woven fabrics, according to claim 1, characterized in that: the detection device further comprises an observation frame (25) and an observation plate (26), wherein the observation plate (26) is obliquely arranged from top to bottom and is fixedly installed on the observation frame (25), the observation frame (25) is rotatably provided with a plurality of detection guide rollers (27) used for guiding the conveyed non-woven fabric, the observation plate (26) is provided with a pressing component, and the pressing component comprises a pressing wheel (30) used for pressing the conveyed non-woven fabric.

7. A detection system for the production of non-woven fabrics, according to claim 6, characterized in that: the observation frame (25) is installed with barn door (31), a plurality of light guide tubes (32) that incline towards observation panel (26) are installed to barn door (31), the axis of light guide tube (32) is perpendicular with the surface of observation panel (26), all install observation lamp (33) in each light guide tube (32).

8. A detection system for the production of non-woven fabrics, according to claim 6, characterized in that: support and press the subassembly still include dancer rools (28) and support and press seat (29), dancer rools (28) horizontal installation is in observation frame (25), dancer rools (28) horizontal installation is in observation board (26), dancer rools (28) wear to locate to support and press seat (29) and with support and press seat (29) cooperation of sliding along the x axle direction, support and press seat (29) to support tightly through the bolt and be fixed in dancer rools (28), support pinch roller (30) to rotate to install in supporting and press seat (29).

9. A detection system for the production of non-woven fabric according to claim 1, characterized in that: the winding device comprises a winding frame (34), two winding rotating rollers (35), a winding roller (36) and two clamping parts (37), wherein the winding rotating rollers (35) are rotatably installed on the winding frame (34) and distributed along the x-axis direction, the winding roller (36) is positioned between the two winding rotating rollers (35), the clamping parts (37) are provided with winding adjusting rods (42) horizontally arranged, the winding adjusting rods (42) penetrate through the winding frame (34) along the x-axis direction and are in sliding fit with the winding frame (34), and the winding adjusting rods (42) are tightly abutted to the winding frame (34) through bolts to be fixed.

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